US2632847A - Pulse forming circuit - Google Patents

Description

March 24, 1953 J. c. REED, JR

I PULSE FORMING CIRCUIT E 5 L U P OUTPUTS INPUT' AT 56 w m E E w W 8 9 I F 5 5 O T T .M A A H T T E R W W R T T U U U E R C 0 O v T S E m w w M P P P T E #7 ll: n |l|| l||| m MI, I |||M h 6 8. 6 6 m. w MW a 'lllrl lllnlollr ll t v. LI 7V: wllllwr h S a:

JOHN c REED JR.

FIG. 2

ATTORNEY Patented Mar. 24, 1953 UNITED STATES PATENT OFFICE PULSE roififfrfg c nema mesne assignments, to the United States America'as represented by the s oretaryor the N we A plication February 4, 1946, Serial 1%.:6459133 4 Claims.

This invention relates to electronic pulse forming circuits and more particularly to double pulse forming circuits useful for radar time communication system's.

\Heretofore, electronic pulse forming circuits were undesirable for use where recovery time of the pulse generating circuit was of prime importance, for example where two successive,

. closely spaced pulses are required.

. The general object or the present invention is to overcome the foregoing difiiculties.

Another object of the present invention to provide an electronic pulse forming circuit in which the recovery time is extremely short.

A further object. is to provide an electronic pulse forming circuit 't'o'for'm two pulses in which the spacing between the pulses can be varied as-a linear function with voltage.

A still further object is to-prov-ide a-double pulse forming circuit controlled by amultivib'rator or other rectangular wavegenerator.

With theseobjects in viewa pulse formingline is inserted in parallel with a transformer in the plate circuit of onetube in a multivibrator such that two pulses areformed, one at the beginning and the other at the end of the gate from the plate circuit, whose characteristics depend on the .pulse forming line and whose time spacing is a linearfunction of voltage applied to the multivibrator.

The above and other objects will be apparent from the following specification when taken with the accompanying drawing, in which:

Fig. 1 is a schematic diagram of one form of the invention; and

. Fig. 2 is a graph of certainwaveformsuseful explaining the operation of, the invention.

Referring to the drawing, this invention coinprises a multivibrator having thermionic tubes II and l! andthe necessary circuit components such as resistors '24,, 25, 2.6., 28,, 1'9, and El and condenser 43,31. pulse forming lihe'Si, and apulse transformer 5|, or other suitable couplin device. A trigger input 61 (Fig.2) is applied at 56 through coupling condenser 45 to initiate the cycle of operation of'the multivibrator and produce in tube ll aplate current waveform 62. At

time 151 when tube I! is cut offend plate current ceases to flow the release of the energy stored' in l '2 merit of energy in the pulse forming line 3| will produce at the output 59 a pulse 69 whose time duration is also dependent on the characteristics of the pulse forming line 3| and is the same duration as that of pulse 66. Thus, it is seen two identical pulses 66 and 630i the same polarity are produced at the outputs 58 and 59. If pulses of the opposite polarity are desired, those shown in Fig. 2 as 6"! and 68 maybe used. Furthermore, the time separation of the two pulses 56 and 69 (or 6? ,and 68) can be made any desired amount by the correct selection of circuit constants and voltages in the multivibrator'and more specifically, as shown in Fig. 1, bycontrolling the bias on grid i3 of tube H by means of the potentiometer 25. The time separation can also varied by the audio input source at 42.

The multivi-brator oi? Fig. l hastwo thermionic tubes ll and H each having at least a plate, a

grid, and a cathode, and these may be in separate envelopes as shown'i'n Fig. l or may be incorporated in a single envelope. The tube H comprisesa plate I2, a control grid I3, and a cathode I l, while thetube I! comprises a plate 8, a control grid i9, and .acathode 2D. The heaters for these cathodes together with their energizing circuits have been omitted inthe drawingfor clearne'ss. sisters-(irate ll isconnected to a source of positive potential 23 through a suitablelresistor Plate IBIof tube i'lisconnected to the same source of positiv'e'potential 23 through thetpulse form-ingline 31 in parallel with the primary 52 of transformer 5|. The pulse forming line iii in parallel with-primary 52 ,replaces the resistor (similar to resistor 28 connected to plate 12 o ft'ube ll) normally used in most multivibrators. Control grid IQ of tube ll in thequ'iesceht condition or this inultivibrator is maintained at a potcnt ia slightly positive with respect to itscathode 2i) bymeans of its onnec+ tion to theposiltive source of potential 23 through resistor 29, whose resistance is large in comparison with resistorfit. The slight positive bias on control grid 1355 due to the flow. of grid' current.

II below cut off during the quiescent period of the multivibrator when tube I! is conducting, and also these same potentials must be suitable for controlling the flow of plate current in tube II during its conducting period.

In the quiescent condition of this multivibrator tube [1 is conducting, since its grid has a slightly positive bias due to its connection to a positive potential through the large resistor 29. This conduction causes the current flowing in the cathode 23 to produce a voltage drop across resistor 4| such that both cathodes I4 and 20, being connected together, are maintained at a positive potential with respect toground. If the potential at the grid I3 of tube I I, as determined by the potentiometer 25, is sumciently below the potential at the cathode I I to" keep "tube II cut ofi,

there will be no conduction in tube I I during the quiescent condition of this multivibrator. quiescent condition occurs during the interval after 122 and before h as shown on the graph of Fig.2, which also shows by wave form 62 the current flowing through tube I7 during the quiescent condition.

At time 131 a negative trigger, such as 6| in Fig. 2, is brought in through coupling condensers 45 and 43 to grid I9 of tube I! to initiate a cycle of operation of the multivibrator. The negative trigger applied to grid I9 reduces the current flowing in cathode 26 of tube I1 thereby reducing the voltage drop across resistor 4| and thus the potential of cathode l of tube II. The trigger used must be of sufficient magnitude that the new potential at cathode I4 will allow tube II to start conducting. As tube I I starts to conduct its plate l2 drops in potential due to current flowing through resistor 28. This drop in potential is coupled through condenser 43 to grid I9 fur- 'ther reducing the current in tube I1. Thus it can be seen a regenerative action takes place so that soon after time n tube I I is cut off and tube I I is conducting.

Now just prior to time t1 condenser 33 was charged to the difference in potential between the grid I9 of tube I1 and the plate I2 of tube II which is the same a s positive potential 23 since 'no current is flowing in resistor 28. At time t1, as the plate I2 drops in potential, the grid l9 will instantaneously drop in potential the same amount driving tube I1 below cut off. The condenser then proceeds to discharge through resistors 29 and 28 principally. This discharge will cause the potential at the grid I9. to rise almost linearly with time toward the positive potential 23. It will continue to rise until, at time tzyit reaches the cut ofi potential of tube I! so that it starts to conduct, raising the potential of cathodes I 4 and 2B, and cutting off tube II so that plate I2 and grid I9 rise. This constitutes a regenerative action similar to that which took place at time 251 so that the multivibrator now reverts to its quiescent condition.

The time from h to i2 is determined by the time necessary for condenser 43 to discharge to the point at which tube I! again starts to conduct. This time is determined by the time constant of discharge of condenser 43 which is primarily determined by the size of resistor 29 and condenser 43; it is also determined by the amount the po tential at grid I9 must rise after time h which in turn is determined by the amount of the drop in potential at the plate l2 at the time h which can be controlled by setting the bias for tube II and thus the amount of current flowing through resistor 28. -This time from t1 to t2 comprises This T the gate mentioned previously and determine the time spacing of the output pulses 65 and 69. A small audio input voltage at terminal 42 applied to grid I3 of tube II through coupling condenser :34 will cause the time from 231 to he to vary at the same audio frequency, the amount of separation being substantially proportional to the amplitude of the audio input voltage.

The pulse forming line 3| of Fig. 1 comprises the small inductors 32, 33, 34, and 35, and the small condensers 31', 38, and 33, and in parallel with primary 52 of transformer 5| is located in the plate circuit of tube IT. This pulse forming line is also known as an artificial line where the inductors and the condensers as lumped constants replace the actual series inductance and shunt capacitance of a real transmission line.

The previously mentioned characteristics of the pulse forming line are determined by the size of the inductors and condensers, the number of each used, and the manner in which they are connected to form the complete line. An artificial line'as shown in Fig. 1, may have its inductors connected in series in one lead of the line, the other lead being simply a short wire or other conductor, and the condensers connected one each from the junctions of the inductors to the other lead. Other connections and number of components than that shown in Fig. 1 are possible; any network having similar external characteristics to that shown in Fig. 1 is equally satisfactory.

The time duration in seconds of a pulse produced by this line would be N: the number of sections;

L=the inductance per section; and, C=the capacitance per section.

Considering the line shown in Fig. 1 as made up of T-sections, the number of sections here is three, the inductance per section is that of either inductors 33 or 34 (inductors 32 and 35 ideally should have a value L/2; however, for convenience a value L may be used), and the capacitance per section is that of condensers ill', 38, or 39. Therefore, a pulse forming line can be designed to generate a pulse of any desired time duration. Thus for a given pulse duration, a certain number of sections will be required if L and C are fixed. However, by reducing L or C or both, and using more sections, a more nearly rectangular pulse will be generated.

, Now the pulse forming line used in this invention is the equivalent of a short-circuited transmission line and is connected in parallel with primary 52 of transformer 5| in the plate circuit of tube I'I. Such a short-circuited line during its pulse forming period may be considered as an equivalent. constant current generator shunted by its characteristic impedance where the constant current I is that which was flowin through the line during the quiescent or conducting period of tube I1, and the characteristic impedance is Zc=\/L/C ohms; L and C being defined as above. For proper operation of this invention, in order to avoid reflections, the characteristic impedance of the pulse formin line should be equal to the input impedance of the primary winding 52 of transformer 5| or to the input impedance of any other coupling device used. If such is the case the energy stored in the magnetic field of the line 3| at time h, when tube I7 is cut ofi, will send a wave I/2'through primary winding 52,- that being the only path remaining, a similar wave 1/2 will travel down line 3| away from plate H! which at the end of time 6 willhave been reflected from the far end of the .line such as to remove all the energy stored in the line, and current will cease to flow in primary winding 52. Likewise at time is, when tube l1 again begins to conduct a current wave I72, opposite in direction to that at time n, will flow through primary winding 52, and a similar wave 1/2 flows through line 31, the two waves added together supplying the current I for tube ll.

Again at the end of time 6 the wave 1/2 will havebeen reflected from the far end of the line so as to restore a current I to the line, ending the wave ofl72 in primary 52, and supplying ing in primary winding 52 at time h will pro-' duce a voltage pulse 66 in secondary winding 53 and also a similar voltage pulse 58 of opposite polarity in secondary winding 54. Likewise the current wave 1/2 flowing in the opposite direction in primary winding 52 at time its will produce a voltage pulse t? in secondary winding 53 having the same polarity as pulse 58 and also a similar voltage pulse 69 in secondary winding E l having the same polarity as pulse 66. Thus the desired double pulse may be obtained at the output terminals 58 and 59 as pulses es and 69 or as pulses 68 and 61 depending on the polarity desired.

It will be seen from the above description that the embodiment of the invention shown in Fig. 1 provides a multivibrator of the one-shot type having a source of audio input voltage'and a trigger input, a pulse forming line, and a pulse transformer by means of which double pulses of a given time duration and variable time spacing may be produced by adjusting certain components or voltages in the circuit.

Various modifications may be made in the invention without departing from the spirit thereof. It is to be understood that while the invention has been disclosed in connection with a multivibrator of the type shown in patent application Serial No. 512,931, filed December 4, 1943, of B. Chance, the invention may be used with any rectangular pulse generating circuit.

However, the multivibrator shown has the advantage that the functioning of the plate circuit of tube I! has no effect on'the regenerative circuit due to the use of cathode coupling, and furthermore, that the gate width and hence pulse spacing is easily controlled as a linear function by the bias voltage on grid 13 of tube II.

It is to be further understood that while the invention has been disclosed in connection with a short-circuited artificial line in parallel with a pulse transformer, the invention may be used with any other type of equivalent network in parallel with any suitable coupling device. However, a pulse transformer having dual secondary windings and dual outputs permits obtaining pulses of like polarity directly.

What is claimed is:

1. An electronic pulse-forming circuit for producing closely spaced double pulses comprising a source of direct current energy, a source of voltage pulses,'-'a-'short 'cir'cuited pulse-forming delay line, "a load circuit, a multivibrator including two electron tubes biased to have one of said electron tubes normally conducting and the other of saidelectron tubes normally non-conducting, means for" energizing said multivibrator from said direct current source, said means including said pulse-forming line in the output circuit of said normally conducting tube, a transformer for coupling said load circuit to said pulseforming line, and means applying said voltage pulsesto bias said non-conducting tube to conduction and said conducting tube to non-conduction to initiate the formation of a rectangular wave form pulse from each voltagepulse, thereby producing two output pulses, one when said normally conducting tube becomes non-conducting and the other when'said normally conducting tube is restored to normal operation, the time separation of said two output pulses being a function of said multivibrator time constants and bias potentials, the time duration of said pulses being a function of said delay line characteristics, and the pulse repetition rate being determined by the repetition rate of said voltage pulse source.

2. An electronic pulse-forming circuit for producing closely spaced double pulses comprising a source of direct current energy, a source of voltage pulses, a short circuited pulse-forming delay line, a load circuit, a multivibrator including two electron tubes biased to have one of said electron tubes normally non-conducting, means for energizing said multivibrator from said direct current source, said means including said pulse-forming line in the output circuit of said normally conducting tube, a transformer for coupling said load circuit to said pulseforming line, means applying said voltage pulses to bias said non-conducting tube to conduction and said conducting tube to non-conduction to initiate the formation of a rectangular wave form pulse from each voltage pulse, thereby producing two output pulses, one when said normally conducting tube becomes non-conducting and the other when said normally conducting tube is restored to normal operation, the time separation of said two output pulses being a function of said multivibrator time constants and bias potentials, the time duration of said pulses being a function of said delay line characteristics, the pulse repetition rate being determined by the repetition rate of said voltage pulse source, and a source of audio frequency voltage applied to bias said multivibrator to control the time separation of said two output pulses at said audio frequency.

3. An electronic pulse-forming circuit for producing closely spaced double pulses comprising a source of direct current energy, a source of voltage pulses, a pulse forming line, a load coupling transformer, a multivibrator circuit including two electron tubes biased to have one of said tubes normally conducting and the other normally non-conducting, means including said pulse-forming line and said transformer for energizing said multivibrator from said director current source, and means applying said voltage pulses to bias said multivibrator to single pulse operation, whereby double output pulses are produced in said line as said normally conducting tube becomes non-conducting followed by restoration to normal conduction.

4. An electronic pulse-forming circuit for producing closely spaced double pulses comprising coupling transformer, a multivibrator circuit in-- cluding two electron tubes biased to have one rent source, means applying said voltage pulses to bias said multivibrator to single pulse operation, whereby double output pulses are produced in said line as said normally conducting tube becomes non-conducting followed by restoration to normal conduction, and a source of audio frequency voltage applied to bias said ,multivibrator' to control the time spacing of said double output pulses,

f JOHN C. REED, JR.

REFERENCES CITED The following references are of record in the file of this patent:

5 UNITED STATES PATENTS Number Name Date 2,188,970 Wilson Feb. 6, 1940 2,221,666 Wilson Nov. 12, 1940 2,255,839 Wilson Sept. 16, 1941 2,266,154 Blumlein Dec. 16, 1941 2,266,401 Reeves Dec. 16, 1941 2,338,512 Harmon Jan. 4, 1944 2,394,389 Lord Feb. 5, 1946 2,405,237 Ruhlig Aug. 6, 1946 15 2,406,978 Wendt et a1 Sept. 3, 1946 M11161 July 20, 1948

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